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Abstract

Introduction

An important goal in managing mechanical ventilation is optimizing key vari-ables such as mean alveolar pressure (PA).

Purpose

Determine the effects of lung mechanics on PA during constant-flow inflation (CFI) and constant-pressure inflation (CPI) in models of nonho-mogenous lung disease.

Methods

We postulated a mathematical lung model consisting of 2 parallel lung units with the airways and the chest wall. Analysis was performed for step inputs of inspiratory flow and pressure while maintaining the same tidal volume, respiratory frequency, and positive end-expiratory pressure. The analysis was performed for purely restrictive, purely ob-structive, and mixed lung disease.

Results

When simulating purely restrictive lung disease, PA was always higher in healthy alveoli than in diseased alveoli, with constant inspiratory flow or constant inspiratory pressure. However, PA in each alveoli was always greater during CPI than during CFI. For purely obstructive lung diseases, PA was always lower in diseased alveoli than in healthy alveoli, with constant inspiratory flow or constant inspiratory pressure. However, PA in each alveoli was always greater during CPI than during CFI. For mixed lung diseases with equal time constants, PA was always higher in diseased alveoli than in healthy alveoli, with constant inspiratory flow or constant inspiratory pressure. However, PA in each alveoli was always the same during CPI as during CFI.

Conclusions

For the same tidal volume, the mean alveolar pressure in different alveoli depends on the type of disease. The difference in mean alveolar pressure between a normal and a diseased alveolus depends on the difference in time constant between those alveoli, regardless of the mode of ventilation.

Keywords

mean alveolar pressure mechanical ventilation lung mechanics alveoli constant flow constant pressure

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Mean Alveolar Pressure during Constant-Flow and Constant-Pressure Inflation of Diseased Lungs

Abstract

Introduction

Purpose

Methods

Results

Conclusions

Keywords

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References